Stable Thermally Activated Delayed Fluorescence‐Sensitized Red Fluorescent Devices through Physical Suppression of Dexter Energy Transfer

Chae Yeon Jeon; Paramasivam Palanisamy; Hyun Seung Lee; Hyuna Lee; Hae Ung Kim; Mi Young Chae; Jang Hyuk Kwon

doi:10.1002/admi.202300147

Advanced Materials Interfaces (May 2023)

Stable Thermally Activated Delayed Fluorescence‐Sensitized Red Fluorescent Devices through Physical Suppression of Dexter Energy Transfer

Chae Yeon Jeon,
Paramasivam Palanisamy,
Hyun Seung Lee,
Hyuna Lee,
Hae Ung Kim,
Mi Young Chae,
Jang Hyuk Kwon

Affiliations

Chae Yeon Jeon: Organic Optoelectronic Device Lab. (OODL) Department of Information Display Kyung Hee University 26, Kyungheedae‐ro, Dongdaemun‐gu Seoul 02447 Republic of Korea
Paramasivam Palanisamy: Organic Optoelectronic Device Lab. (OODL) Department of Information Display Kyung Hee University 26, Kyungheedae‐ro, Dongdaemun‐gu Seoul 02447 Republic of Korea
Hyun Seung Lee: Organic Optoelectronic Device Lab. (OODL) Department of Information Display Kyung Hee University 26, Kyungheedae‐ro, Dongdaemun‐gu Seoul 02447 Republic of Korea
Hyuna Lee: Organic Optoelectronic Device Lab. (OODL) Department of Information Display Kyung Hee University 26, Kyungheedae‐ro, Dongdaemun‐gu Seoul 02447 Republic of Korea
Hae Ung Kim: Organic Optoelectronic Device Lab. (OODL) Department of Information Display Kyung Hee University 26, Kyungheedae‐ro, Dongdaemun‐gu Seoul 02447 Republic of Korea
Mi Young Chae: Organic Optoelectronic Device Lab. (OODL) Department of Information Display Kyung Hee University 26, Kyungheedae‐ro, Dongdaemun‐gu Seoul 02447 Republic of Korea
Jang Hyuk Kwon: Organic Optoelectronic Device Lab. (OODL) Department of Information Display Kyung Hee University 26, Kyungheedae‐ro, Dongdaemun‐gu Seoul 02447 Republic of Korea

DOI: https://doi.org/10.1002/admi.202300147
Journal volume & issue: Vol. 10, no. 15
pp. n/a – n/a

Abstract

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Abstract To date, thermally activated delayed fluorescence‐sensitized fluorescent organic light‐emitting diodes (TSF‐OLEDs) have undergone substantial research to achieve high efficiency and good operational stability in wide color gamut regions. Usually, to achieve a highly efficient TSF device, the Förster resonance energy transfer rate (kFRET) should be enhanced, whereas the Dexter energy transfer rate (kDET) should be suppressed. Even though highly efficient devices are achieved in all RGB color regions by satisfying the BT2020 requirements, achieving long device lifetimes is still challenging. Herein, a highly stable red‐TSF device is reported by adopting a new Dexter energy transfer suppressive layer (DSL) adjacent to the main emissive layer. Here, the DSL can improve the distance between the excitons generated from the host‐TADF layer and the final dopant (FD) of the TSF device, which allows for suppressing the kDET. Furthermore, the detailed device mechanistic pathways are analyzed by varying the DSL doping concentration with different thicknesses in different positions. Among the fabricated devices, the DSL‐TSF device manifested a longer operational lifetime (LT95) over 370 h at 5000 cd m‐2 and reduced efficiency roll‐off compared with TSF devices. Such long lifetime and high stability in DSL‐TSF OLEDs are owing to the decreased kDET than TSF devices.

Published in Advanced Materials Interfaces

ISSN: 2196-7350 (Online)
Publisher: Wiley-VCH
Country of publisher: Germany
LCC subjects: Science: Physics; Technology
Website: https://onlinelibrary.wiley.com/journal/21967350

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